A Reluctant Dance Towards Europa

or, Why A Credible Europa Mission is Likely to Cost ~$2B

For the last two years, NASA has been the shy partner refusing to get on the dance floor, and Congress has been the aggressive partner insisting on a dance now. Recently, NASA has said maybe on another night but only if it's a cheap date. While NASA says no for now, Congress looks to be willing to slip the band a cool $100M – on top of $150M already paid – to keep the music playing, but (to keep the metaphor going) has not been willing to fully commit itself to paying the bigger bill to rent the dance hall.

The dance, of course, is the continuing attempt by Congress to have NASA commit to a mission to explore Europa, and NASA managers' attempts to delay a mission well into the 2020s. NASA is also seeking ideas for alternatives to the current $2B Europa Clipper concept that would cost no more than $1B but that also would presumably be much less capable.

(I should make it clear that NASA's managers in this context are its most senior managers who have to try to balance the demands of an underfunded human spaceflight program against requests for several exciting science missions. They are in a tough spot between the restrictions placed on them by the President's budget office and Congress' requests, with too little money the common denominator.)

Compared to the budget waltz, the scientific case for a mission to Europa is compellingly simple. After the Earth, Europa is considered by many scientists to be the most likely location in the solar system as a home to present life. It has the key ingredients: an outer layer with lots of water (more than in the oceans of Earth) in contact with the rocky core (source of key elements needed to build the molecules essential for life) and energy (from the tidal heating supplied by Jupiter). And Europa has had a lot of time for life to evolve. Its oceans should have been present for most of the life of the solar system. (This distinguishes it from Enceladus where the weaker tidal flexing of Saturn may allow its internal ocean to freeze for long periods of time.) The recent observation of possible plumes spewing water into space where Europa's ocean could be easily sampled has just raised the desire for a dedicated Europa mission.

NASA / JPL-Caltech

Europa Clipper summary

The Europa Clipper would replace a short-lived Europa orbiter concept with a spacecraft that would fly past the moon several dozen times with a highly capable instrument payload. At each encounter, the instruments would do low- to medium-resolution studies before and after closest encounter, but would do high resolution studies during the brief period when the spacecraft is less than 1000 km from the surface.

The Science Goals

In the 1990s and early 2000s, the Galileo orbiter made eleven of flybys past Europa. That mission all but proved the existence of a liquid ocean beneath the moon's icy shell and globally mapped the surface features and composition. Galileo, however, had a crippled main antenna that reduced the returned data to a tiny trickle of what had been planned, so medium and high resolution mapping of the moon covers only small areas. The spacecraft's vintage 1970's technology instruments also lacked the sophistication to identify important substances in the icy surface. It also did not carry instruments that could probe the structure of the icy shell to look for lakes within the shell or study the shell's interface with the ocean.

The standard progression for exploring a world is first flyby it (which Galileo did), then orbit it for globally studies, and then land on it for intensive studies in a single location. Unfortunately, Europa sits well within Jupiter's harsh radiation belts, and any affordable orbiter would have weeks to a handful of months to complete its studies and would carry a minimal instrument compliment.

JPL's engineers and scientists have developed an alternative strategy for the proposed Europa Clipper mission: Fly a highly capable spacecraft that orbits Jupiter, but that toe dips into the radiation belt and conducts its science during several dozen flybys. The radiation challenges are still significant, but the science that would have carried a cost of >$4B as an orbiter can now be done for ~$2B.

The several dozen flybys is key to the Europa Clipper's ability to replace an orbiter mission with a multiple-flyby mission.

NASA/JPL

High Resolution Imaging on Europa

During the few minutes around closest encounter, high resolution studies are done only for a narrow swath along the ground track immediately below the spacecraft's flight.

NASA / JPL-Caltech

Europa Clipper regional imaging

Over several dozen flybys, the high resolution measurements build up into regional studies.

NASA / JPL-Caltech

Europa Clipper global coverage

The combination of low, medium, and high resolution measurements add up to an understanding of Europa as a world over several dozen orbits. (Acronyms: 13F7 - name for a specific concept for a set of flybys; COT-4 - name for the final campaign (of four) for the Europa Clipper mission; SWIRS - Short-wave infrared spectrometer that would map the composition of the surface.)

I'll focus on just one set of requirements and how they link to several key investigations. To ensure that proposed mission achieves global coverage, the science team has divided Europa's map into 14 panels. The science goals require that the spacecraft fly over at least 8 of these panels at altitudes of less than 400 kilometers with a desired goal of 11 panels. Within each panel, the requirements specify that at least two close flybys occur in each on the Jupiter-facing hemisphere of Jupiter and three on the anti-Jupiter face. If the minimum 8 panels are evenly distributed between the pro- and anti-Jupiter hemispheres, then 20 flybys are needed to meet the minimum science goals.

This one set of requirements for regional measurements within a panel and a distribution of regional studies across the Europan globe enables several key studies:

Characterize the ice shell and any subsurface water, including their heterogeneity, ocean properties, and the nature of surface-ice-ocean exchange.

Characterize the distribution of any shallow subsurface water and the structure of the icy shell.

Search for an ice-ocean interface.

Correlate surface features and subsurface structure to investigate processes governing material exchange among the surface, ice shell, and ocean.

Characterize regional and global heat flow variations.

Understand the habitability of Europa's ocean through composition and chemistry.

Characterize the composition and chemistry of the Europa ocean as expressed on the surface and in the atmosphere

Determine the role of Jupiter's radiation environment in processing materials on Europa

Characterize the chemical and compositional pathways in Europa's ocean.

Understand the formation of surface features, including sites of recent or current activity, and characterize high science interest localities." (Quotes are from the Europa Clipper Science Traceability Matrix.)

The science goals similarly require a number of well distributed flybys to study the interaction of Europa's ocean with Jupiter's intense magnetosphere to estimate the depth and salinity of the ocean and to study tides to estimate the ice shell's thickness.

The current Europa Clipper mission concept goes well beyond the minimum science goals to deliver on almost all the extended goals that the science community has set. However, cutting the current mission concept from its 45 Europa flybys to a minimum of 20 or fewer flybys seems unlikely to cut the mission costs in half. Once you build and fly a spacecraft to Europa that can withstand 20 encounters, operate a suite of instruments, and return a large volume of data between encounters, I suspect that you've already incurred most of $2B cost (but remember that I am neither an engineer nor a planetary scientist).

Is Cheaper Credible?

NASA managers have formally asked if a credible Europa mission could be done for half the Clipper cost estimate—around $1B. This is a good news/bad news scenario. NASA took the initiative to propose an in-depth study by suggesting spending $15M next year ($85M less than the House of Representatives appears ready to approve for next year, see below). However, next year's study would be followed by several years before any mission conceived would actually begin development and a decade or more before it might launch.

NASA issued a Request For Information on concepts for a $1B mission. It has required that proposers, "meet the majority of the five science goals set forth in the Decadal Survey [priorities set by the scientific community], including the goal to characterize scientifically compelling sites to prepare for a potential future lander mission to Europa." Those scientific goals are, in priority order, to:

Characterize the extent of the ocean and its relation to the deeper interior;

Characterize the ice shell and any subsurface water, including their heterogeneity, and the nature of surface-ice-ocean exchange;

Understand the formation of surface features, including sites of recent or current activity, and identify and characterize candidate sites for future in situ exploration;

Understand Europa's space environment and interaction with the magnetosphere.

While characterizing landing sites for future in situ exploration is the fourth scientific priority in the Planetary Decadal Survey, NASA places high programmatic priority on this goal to enable a potential future lander mission to Europa." (From the Request for Information.)

The request goes on to list the challenges of implementing the mission. "The primary challenges facing any mission to Europa involve the harsh radiation environment and planetary protection requirements...Planetary Protection requirements for Europa are very strict and involve ensuring that the probability of introducing a viable Earth organism into Europa is [less than one in 10,000]."

The request's details make it clear that proposers must do a solid amount of science and engineering analysis to show that they have a credible concept that could cost less than $1B (not including the launch costs) and make their case in 15 pages.

It is common for government agencies to issue these "Requests for Information" to learn whether an idea is credible and worth pursuing. This request doesn't commit NASA to any follow up studies, but if its managers judge any of the proposals to be credible, it presumably would follow through with more detailed analyses.

Is a $1B mission idea credible? I did a thought experiment in a previous post and concluded that technically it likely is. The Juno spacecraft that will orbit and study Jupiter cost ~$700M. A mission to fly by Jupiter's moon Io, deeper in Jupiter's radiation field, six or so times has been estimated to cost ~$1B. The European's JUICE mission will reach Jupiter next decade, flyby Europa twice, and then orbit the moon Ganymede for ~$1.2B.

If the goal simply is to fly by Europa a few times with a spacecraft with a small number of instruments, then by analogy with these other Jupiter missions, it likely can be done for ~$1B. The bar, though, for a scientifically credible mission is higher. A follow-on mission has to substantially enhance our scientific understanding of Europa to justify a cost of $1B to $2B. Most of the key studies identified by the science team require numerous flybys distributed across the globe.

However, Europe's JUICE 2020's JUICE mission to the Europa system is committed to two flyby of Europa with a highly capable spacecraft and instrument suite. To be justified, a NASA mission must produce significantly better science than the already funded JUICE mission will. (While the JUICE mission, which is still in design, it has committed to just two flybys of Europa. I suspect that if the engineers conclude it is safe, the mission's managers will consider one or two additional flybys closer to launch.)

So is there hope for a $1B mission that is scientifically compelling? Color me skeptical (and several of NASA's managers are reported to have said they are skeptical, too), but if there is, I suspect that it will come in one of two forms:

A proposal suggests a clever way to redefine the science goals in a way that returns the core science with a simpler and cheaper spacecraft. The team that proposed the Juno mission on its way to Jupiter did this for studies of Jupiter's deep atmosphere and interior. The current Europa Clipper multi-flyby proposal redefines the science goals from previous orbiter proposals to substantially cut costs. Is there another option that can cut costs substantially again?

A proposal combines limited regional studies with flights through the possible plumes of Europa to directly measure water, and possibly life, expelled either from a lake within the shell or directly from the ocean. (However, remember that only one of several studies saw data that suggested plumes were present and those measurements were near the limit of detection. The plumes may be ephemeral or not even exist. Justifying a mission on the current plume data seems risky to me; a better strategy would seem to be to have a viable mission without the plumes but carry the already planned instruments that would also be useful to study the plumes. The JUICE mission team is already planning this.)

In a few months, we are likely to learn whether NASA received any proposals it considers worthy of further study. They key, though, will be whether the science community agrees that the mission meets the core requirements for understanding Europa. If it doesn't, then the community seems likely to recommend waiting until budgets allow the right mission to be flown. Missions to each outer planet or their moons occur only every couple of decades. Why do a sub-par job on the next mission to Europa and then have to do it over a decade or two later to get it right?

The Politics

In the introduction to this post, I said that NASA (and the President's budget office that writes NASA's budget requests) and Congress disagree on whether a Europa mission should begin now or wait to begin development several years from now.

The root of the disagreement, as in so many relationships, is money. Jupiter's harsh, electronics-frying radiation belts, make any mission that does more than a handful of flybys a technically challenging – read expensive – proposition. More than a decade's worth of technology development and mission studies has provided the solutions to most of the technical challenges. JPL's scientists and engineers have developed a killer proposal for a dedicated multi-flyby Europa Clipper mission. At ~$2B, this mission would be cheaper than the Curiosity rover mission currently exploring Gale crater on Mars.

Unfortunately, NASA's budget is oversubscribed. The only way to fit the Clipper mission into the budget is to either increase NASA's budget by several hundred million dollars a year for several years (which I would support as a US taxpayer!) or take the funding from other NASA programs.

We are left with this strange waltz in which Congress, which ultimately sets NASA's budget, has not increased the overall budget enough to fully fund the Clipper mission, but over the last two years provided $150M for advanced development work. This year, the House of Representatives is proposing to put another $100M in the pot for next year. If the Senate continues its previous support, it is likely to substantially match this funding.

At the other side of the dance floor, the President's budget managers and NASA's managers have made it clear that they don't want to commit to any Europa mission this decade because of the funding constraints. They also seem reluctant to commit to any $2B-class science mission because the last two large science missions (the James Webb Space Telescope and the Curiosity rover) went well over budget, which caused substantial harm to the overall science program.

As a result, today NASA is spending $150M because it's legally required to (Federal budgets in the US are laws) to advance a mission its senior managers don't want to do, at least for this decade.

The House of Representatives has released details of its proposed budget for next year. Where NASA proposed to spend $15M to study $1B mission concepts, the House is proposing to spend $100M. Under the House's bill none of the funding could go towards a $1B mission (which it doesn't see as credible) but only towards the full Europa Clipper mission.

We will have to wait for several weeks to see what the Senate proposes. It will be several months before we learn what the two houses of Congress ultimately compromise on for next year.

Comments:

Messy: 05/14/2014 04:29 CDT

the problem seems to be that NASA is scared that it might actually find life IN Europa.
Now would be a perfect time to do a repeat of the Viking experiments, modified with what we know now, but I don't think they'd go for that either.

Messy: 05/14/2014 04:33 CDT

If I remember correctly, they didn't want to do New Horizons and did their damnedest to stop DAWN.
That's why we need lobbyists like you guys.

Vladimir H.: 05/14/2014 05:35 CDT

After reading this (not short to be honest but very entertaining ) article my opinion is that, if it is possible, I would rather see cooperative project NASA- ESA JUICE mission. Last time Cassini mission went realy well and I don't see reason why we(as humans) should have two missions to Galilean satellites at one time. So Rather than developing cheap spacecraft let's join forces and buy for $ 1B more Europa flyby's and more science goal's.

Paul McCarthy: 05/15/2014 01:53 CDT

Science and human knowledge ratchets forward in leaps and bounds: sometimes leapfrogging, sometimes discovering short-cuts. What's often needed is some new technological quirk, or new insight or discovery, which then allows the past log-jam to be bypassed, the Gordian Knot to be cut. The Europan plumes are one such complete game-changer. A dramatic new route now potentially opens up.
Clearly, first the plumes must be verified. But this should be relatively kindergarten with repeat observations and the technological armada now available.
If they exist, then open-minded, go-for-the-jugular science and analysis says go straight for them -- bypass all the rest (or rather, regard the rest as collateral). They can reveal 95% of the story directly.
In other words, if they exist, then design unilaterally to sample the plumes (and preferably sample-return them) at minimum cost and minimum delay. Add complementary instruments only according to budget, feasibility, and if complementary to JUICE. Those "tolerated" instruments, plus the plume info, plus the JUICE instruments, will, in fact, produce an optimum overall yield. Put the package on the SLS for a 2-yr flight time (scoop JUICE along the way), and plan subsequent missions based upon the revelatory results!

stone: 05/15/2014 08:48 CDT

A NASA- ESA JUICE mission? The last few years made it 100% clear that cooperation on mission level is not working with NASA. The Exomars disaster and the SOPHIA killings upset the Germans and the Italians, the French had always problems with NASA. So the support for a cooperation with NASA is very limited. This is only at mission level, an the level of instruments the cooperation would be welcomed from most.

reader: 05/15/2014 02:38 CDT

Cut the 2020 Curiosity re-run and suddenly Europa is within reach. But we all know that this is a taboo ..

DavEd: 05/15/2014 08:05 CDT

Paul McCarthy, I hear you, and you are correct, in that what's needed is a quirky new technology.. and HERE YOU GO.
My company can bring you to Europa, and beyond. We have been developing a new propulsion system, which will revolutionize space travel as we know it. I'm talking about internally generated, vectored force similar to a UFO. An efficient, smooth, electric propulsion system which doesn't expel any reaction mass. Its here guys.... Its going to change everything.

Paul McCarthy: 05/16/2014 02:09 CDT

Hmmm; not sure whether you missed the point DavEd. But good luck to you.

DavEd: 05/16/2014 07:24 CDT

With respect, Paul I think you may have missed the point. But that's ok..
It's ALL about to change. It's OK if you don't believe me now.

Enzo: 05/16/2014 07:43 CDT

@DavideE,
Is it based on quantum vacuum plasma thruster ?
http://en.wikipedia.org/wiki/Quantum_vacuum_plasma_thruster

DavEd: 05/16/2014 12:42 CDT

Not one of the several methodologies we've pursued here, although plausibly valid. Currently our 360lb prototype can produce over 300 ft/lbs of smooth vectored thrust. A boat test is coming shortly and we plan to get it up on plane, with no propeller, or propellant.. Brand new breakthroughs here.. Europa here we come.. :)

Enzo: 05/17/2014 10:35 CDT

In any case, the main problem for Europa is not technological, but political : we would have had a mission there already if it weren't for NASA's Mars obsession and consequent unbalanced fund allocation.
A better propulsion method would help, but it is insufficient without a real will to set aside the necessary funds.

Torbj??rn Larsson: 05/18/2014 12:02 CDT

Well, since the SLS comes for free and the plumes are likely confirmed eventually (cmp Enceladus), a larger craft that can make a sample return after a few dips in the plumes may be a crude 1 GUSD mission.
But the EC is the better overall science packet. PlanSoc has had articles on putative plate tectonics in Europa's ice shell, which would be the only 2nd planet known to have it.
@Enzo: Not NASA's obsession, but the US planetary science community's:
"2003-2013, New Frontiers in the Solar System
Jupiter and Europa as viewed by New Horizons in 2007
New Frontiers in the Solar System: An Integrated Exploration Strategy 2003-2013 was published in 2003.[11] The committee producing the survey was led by Michael J. Belton. The 5 panels focused on the inner planets, Mars, the Giant planets, Large satellites and Astrobiology. The survey placed heavy emphasis on Mars exploration including the Mars Exploration Rovers, ..."
[ http://en.wikipedia.org/wiki/Planetary_Science_Decadal_Survey ]

Torbj??rn Larsson: 05/18/2014 12:20 CDT

Also, I think there are technical challenges with sample return. The likey plumes may have 10 times the flow of Enceladus, but due to the higher gravity they don't go free (E ring), they go to a lower height.
The Enceladus plume may be sampled by improved aerogels so that the ice et cetera isn't as heated. But I bet the Europa samples will need a much faster pass, so the samples will be less valuable. A landing sampler which can take the outfall beneath the plumes would be better.

DavEd: 05/20/2014 08:18 CDT

Enzo I hear you. It does seem that the problem is not technical, but more political. However I believe that is not the case, and here's why: We actually DON"T have the technical.. We only think we do..
How much it cost these days to shoot off an SLS rocket? A half a billion dollars? If that portion could be saved, would that be appealing to the guys that make the decisions? WHAT IF we had a propulsion system that defies our current way of thinking entirely. Quiet, no reaction mass, electric propulsion.. Oh, the mission capabilities... What if I said WE DO have it? There have been MAJOR breakthroughs recently and the it is our belief that the entire space program will be flipped on its ear soon. Almost all this mission conjecture is moot. Lets wait 1 year and talk again..
Things are about to change.